Reflective Mobile Phone Cinema Lens

Abstract

A reflective mobile phone lens, comprising a semi-permeable semi-reflecting mirror (5), a concave spherical reflecting mirror (4) and a mobile phone (1) screen; the mobile phone (1) screen serves as a display screen to display an image; light passes through the semi-permeable semi-reflecting mirror (5) and arrives at the concave spherical reflecting mirror (4), and then is reflected by the concave spherical reflecting mirror (4) back to the semi-permeable semi-reflecting mirror (5), and is reflected by the reflective surface of the semi-permeable semi-reflecting mirror (5) onto the mobile phone (1) screen. The mobile phone lens enables watching an online movie or playing a virtual reality game on the mobile phone (1) to have a good effect like watching a movie on a big screen in a cinema.

Description

BACKGROUND OF THE INVENTION

[0001] 1. Technical Field

[0002] The present invention relates to an optical magnifying device, in particular to a device for magnifying a mobile phone screen.

[0003] 2. Description of Related Art

[0004] With technological development, mobile phone display screen pixel resolutions are becoming higher and higher, and pixel resolution for a screen as small as about five inches is 1920*1080, sometimes reaching 2560*1440 and can even be developed to 4K ultra-high definition pixel resolution which is 3840*2160. The pixel resolution of small screens is the same as that of the most advanced large television, and the pixel density has already exceeded the human eye's recognition range. An online video can be watched on a mobile phone quite conveniently, the economic efficiency is quite high, and the advantages of being private and not affecting other people and the advantages which cannot be achieved by a large television are also achieved. However, not only is the definition requirement needed when people watch movies, but also the shock brought by large-breadth IMAX is needed, and details which cannot be clearly seen with the naked eye also need to be recognized, so that the problem of narrow width still exists when movies are watched on a mobile phone.

BRIEF SUMMARY OF THE INVENTION

[0005] In order to overcome the defect, the present invention provides a reflective mobile phone lens according to which a concave spherical reflecting mirror is used for magnifying a mobile phone screen.

[0006] According to the technical scheme adopted by the present invention for solving the technical problem, a mobile phone serves as the display component of the device, light passes through a semi-permeable semi-reflecting mirror which is in front of the eyes and oblique relative to the light, arrives at a concave spherical reflecting mirror or a concave non-spherical reflecting mirror which is opposite the eyes, then is reflected by the concave spherical reflecting mirror back to the semi-permeable semi-reflecting mirror, and is reflected by the reflective surface of the semi-permeable semi-reflecting mirror onto the mobile phone screen placed above the semi-permeable semi-reflecting mirror.

[0007] The present invention has the beneficial effects of the mobile phone lens which is formed by a concave spherical reflecting mirror method is small in size and low in weight, avoids the problem of chromatic aberration of a convex lens, avoids the shrinkage problem which cannot be solved by an injection-molded convex lens, and avoids the weight problem caused by the thickness of a large convex lens. Advanced mobile phone equipment is adopted by the lens, not only is the entertainment enjoyment of an IMAX huge-screen cinema or a virtual reality game brought to people, but also a piece of image displaying or high-end monitoring equipment which can be used for meeting certain working and studying requirements can be constructed for people easily.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0008] FIG. 1 is an equivalent light path diagram of an ordinary 2D image;

[0009] FIG. 2 is a light path diagram of a concave spherical reflecting mirror magnifying device;

[0010] FIG. 3 is a stereoscopic diagram of an ordinary 2D image magnifying device;

[0011] FIG. 4 is an equivalent light path diagram of a 3D magnifying device;

[0012] FIG. 5 is a concave spherical reflecting mirror for 3D purpose;

[0013] In FIGS: 1 mobile phone, 2 eyepiece magnifying lens, 3 magnifying lens, 4 single-concave-spherical lens, 5 semi-permeable semi-reflecting mirror, 6 double-concave-spherical reflecting mirror, 7 3D isolating light barrier.

DETAILED DESCRIPTION OF THE INVENTION

1. A Light Path of an Ordinary 2D Image is Magnified

[0014] Light is reflected by the same semi-permeable semi-reflecting mirror (5) onto the same single-concave-spherical reflecting mirror (4) (FIG. 2 and FIG. 3), and the light is reflected back by a concave spherical reflecting mirror and then reflected by the reflective surface of the semi-permeable semi-reflecting mirror onto a mobile phone (1) screen. An equivalent magnifying lens (3) (FIG. 1) based on the magnifying principle of the concave spherical reflecting mirror is arranged, a two-eye light path equivalent diagram 1 is provided, and an eyepiece magnifying lens (2) in the diagram slightly deviates from the light towards the middle, so that the uncomfortable feeling of cross-eye people is avoided. The eyepiece magnifying lens also has the function of enlarging the field of view, and the magnified breadth (FIG. 2) can be increased.

2. 3D Light Path

[0015] Light is reflected by the semi-permeable semi-reflecting mirror to the corresponding concave spherical reflecting mirror bodies (the equivalent diagram 4) of a double-concave-spherical reflecting mirror (6) respectively, and the light is reflected back by the concave spherical reflecting mirror bodies and then reflected by the reflective surface of the semi-permeable semi-reflecting mirror onto a left image and a right image, being parallax, displayed by the mobile phone screen. A 3D isolating light barrier (7) is arranged between light paths of the two eyes for isolation, and a two-eye light path equivalent diagram 4 is provided. In the diagram, two eyepiece magnifying lenses slightly deviate towards the two ends, so that the situation where the distance between the center of the left parallax image and the center of the right parallax image being larger than the pupil distance between the two eyes is avoided. The double-concave-spherical reflecting mirror (6) is formed by assembling the two concave spherical reflecting mirror bodies together in the left-right direction (FIG. 5), the area of the assembled concave spherical reflecting mirror bodies is as large as the area of two 2D single-concave-spherical reflecting mirrors (4) so that the concave spherical reflecting mirror bodies and the 2D single-concave-spherical reflecting mirrors (4) can be interchanged in a device, and both the 2D purpose and the 3D purpose are achieved through the detachable 3D isolating light barrier.

3. Concave Spherical Reflecting Mirror

[0016] The concave spherical reflecting mirror can be a single-concave-spherical reflecting mirror or a double-concave-spherical reflecting mirror, the spherical curvature of the single-concave-spherical reflecting mirror is consistent with the spherical curvature of the double-concave-spherical reflecting mirror, the area of the single-concave-spherical reflecting mirror and the area of the double-concave-spherical reflecting mirror are the same and consistent with the area of a fixed interface of a lens device, and interchange of the 2D purpose and the 3D purpose is achieved. The concave spherical reflecting mirror includes a concave non-spherical reflecting mirror used for phase difference correction.

4. Light Path Design

[0017] The light path design is conducted with a square as a frame (FIG. 2), and the width of the mobile phone screen which is prepared to be adopted serves as the norm of the side length of the square. The concave spherical reflecting mirror is arranged opposite to the eyes, and the height of the concave spherical reflecting mirror is also basically equal to that of the square frame. The semi-permeable semi-reflecting mirror is arranged along the diagonal line of the square, and the long side of the semi-permeable semi-reflecting mirror is basically equal to the length of the mobile phone screen. The positions of the eyes are made to approach the concave spherical reflecting mirror to the maximum extent, so that a light path which is as short as possible is obtained. The curvature (c) of the concave spherical reflecting mirror is based on the norm where the incident light (a), emitted from an eyepiece in the diagram for seeing the edge of the screen is parallel to the reflected-out emergent light (b), and the remaining focal length can be matched and corrected by means of the eyepiece magnifying lens.

Claims

1. A reflective mobile phone lens used for watching a movie or playing a virtual reality game on a mobile phone, comprising a semi-permeable semi-reflecting mirror, a concave spherical reflecting mirror and a display component, characterized in that a mobile phone serves as the display component of the device, and light passes through the semi-permeable semi-reflecting mirror which is in front of the eyes and oblique relative to the light, arrives at the concave spherical reflecting mirror or a concave non-spherical reflecting mirror which is opposite the eyes, then is reflected by the concave spherical reflecting mirror back to the semi-permeable semi-reflecting mirror, and is reflected by the reflective surface of the semi-permeable semi-reflecting mirror onto a mobile phone screen placed above the semi-permeable semi-reflecting mirror.

2. The reflective mobile phone lens according to the claim 1, characterized in that the concave spherical reflecting mirror can be a single-concave-spherical reflecting mirror or a double-concave-spherical reflecting mirror, and the double-concave-spherical reflecting mirror is composed of a left concave spherical reflecting body and a right concave spherical reflecting mirror body; the area of the single-concave-spherical reflecting mirror and the area of the double-concave-spherical reflecting mirror are the same and consistent with the area of a fixed interface of a lens device, and the single-concave-spherical reflecting mirrors and the double-concave-spherical reflecting mirror can be exchanged.

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